System And Method For Estimating Bandwidth Requirements Of  And Allocating Bandwidth To Communication Devices Operating In A Network

ABSTRACT

A system including a base station and a plurality of stations. The base station is configured to estimate bandwidths used by the plurality of stations based on packets transmitted by the plurality of stations during a first period. The base station is further configured to selectively allocate timeslots to the plurality of stations for transmission of packets to the base station during a second period following the first period. Durations of the timeslots are based on the estimated bandwidths. The plurality of stations are configured to transmit packets to the base station in the timeslots during the second period.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.12/351,097 (now U.S. Pat. No. 7,957,347), filed Jan. 9, 2009, which is acontinuation of U.S. patent application Ser. No. 10/934,526 (now U.S.Pat. No. 7,477,621), filed Sep. 7, 2004. The disclosure of the aboveapplication is incorporated herein by reference in its entirety.

BACKGROUND

1. Field of the Invention

The present invention relates to information communication systems. Moreparticularly, the present invention relates to a system and method forestimating bandwidth requirements of and allocating bandwidth tocommunication devices operating in a network.

2. Background Information

A conventional wireless local area network (WLAN) is based on a cellulararchitecture in which the system is divided into cells. Each cell,referred to as a Basic Service Set (BSS), is controlled by a BaseStation, referred to as an Access Point (AP). The APs of the cells areconnected to each other through a suitable type of backbone, referred toas a Distribution System (DS). The entire interconnected WLAN, includingthe different cells, their respective APs and the DS is referred to asan Extended Service Set (ESS).

One or more clients or stations within a cell can communicate using acarrier sense multiple access with collision avoidance (CSMA/CA)protocol for medium access control. In a CSMA/CA protocol, a stationdesiring to transmit senses the channel. If the channel is busy (i.e.,some other station is transmitting), then the station will defer itstransmission to a later time. If the channel is sensed to be free atthat time, then the station is allowed to transmit. The CSMA/CA protocolworks well when the channel is not heavily loaded, allowing the stationsto transmit with minimal delay. However, two or more stations maytransmit at the same time, causing collisions, if the stations sensethat the channel is free and decide to transmit at once.

To overcome such problems, conventional WLANs use a collision avoidancemechanism with a positive acknowledgment scheme. In such a scheme, astation desiring to transmit will sense the channel. If the channel isbusy e the station will defer transmission. If the channel is free for aspecified amount of time, then the station (the “sending station”) isallowed to transmit. The receiving station will check the cyclicredundancy code (CRC) of the received frame and send an acknowledgmentframe (ACK). If the sending station receives the ACK, then no collisionhas occurred. However, if the sending station does not receive the ACK,then the sending station will retransmit the frame until it isacknowledged or thrown away after a given number of retransmissions.However, in a WLAN, all stations may not be able to hear each other.Thus, a station may desire to transmit and senses the channel to befree, although the channel may not necessarily be free.

To reduce the probability of two or more stations colliding because theycannot hear each other, conventional WLANs use a virtual carrier sensemechanism. In such a mechanism, a station that desires to transmit willfirst transmit a short control frame, referred to as a Request to Send(RTS). The RTS includes the source, the destination and the duration ofthe frame to be transmitted and the respective ACK. If the channel isfree, the destination station will respond with a response control framereferred to as a Clear To Send (CTS). The CTS includes the same durationinformation as the RTS. All stations receiving either the RTS and/or CTSwill set their respective virtual carrier sense indication, referred toas Network Allocation Vector (NAV), for the given duration, and will usethis information when sensing the channel. The virtual carrier sensemechanism reduces the probability of a collision in the receiver area bya station that cannot be heard by the transmitter to the short durationof the RTS transmission, because the station will hear the CTS packetand “back off” the channel until the end of the transaction. A backoffmethod is used to resolve contention between different stations desiringaccess to the channel. A binary exponential backoff algorithm requireseach station, when the channel is busy, to choose a random numberbetween zero and a given number, and wait for this number of time slotsbefore accessing the channel, checking whether another station hasaccessed the channel before transmitting.

The above discussion applies to the Distributed Coordinated Function(DCF) mode. In the DCF node, there is no central control, and stationscompete for transmission time. In contrast in the Point CoordinatedFunction (PCF) mode, the AP polls the stations, inquiring whether any ofthe stations have frames to transmit. Since transmission order iscompletely controlled by the AP in PCF mode, no collisions occur. In PCFmode, the AP broadcasts a beacon frame periodically. The beacon framecontains various system parameters. The beacon frame also invitesstations to sign up for polling service. Once a station has signed upfor polling service at a certain rate, the station is allocated acertain fraction of the total bandwidth available for transmission.

Conventional WLANs use an interframe time interval to allow the DCF andPCF modes to coexist within a cell. After a frame is transmitted, agiven amount of dead time is required before any station can transmit aframe. The shortest interval is the Short InterFrame Spacing (SIFS)time. SIFS is used to allow stations in a single dialog the chance to gofirst, including letting the receiver send a CTS to respond to a RTS,letting the receiver send an ACK for a frame fragment or full data frameand letting the sender of a fragment burst transmit the next fragmentwithout having to send a RTS again. There is always exactly one stationthat is entitled to respond after a SIFS interval. If the station failsto make use of its chance to transmit and a PCF InterFrame Spacing(PIFS) time elapses (equal to SIFS plus a specified slot time), the APmay send a beacon frame or a poll frame. Such a mechanism allows astation sending a data frame or frame fragment sequence to finish itsframe without other stations interfering, but gives the AP a chance toaccess the channel when the previous sender is done without having tocompete with the stations. If the AP has nothing to transmit and a DCFInterFrame Spacing (DIFS) time elapses (equal to PIFS plus onetimeslot), any station may attempt to acquire the channel to send a newframe. Contention rules apply, and the binary exponential backoffalgorithm may be needed if a collision occurs. The longest time intervalis the Extended InterFrame Spacing (EIFS) time interval. EIFS is usedonly by a station that has received a bad or unknown frame to report thebad frame.

Thus, to allocate bandwidth in conventional WLANs, the stations mustcontend with substantial processing overhead to compete for availablebandwidth when there is no central control (e.g., in DCF mode), or mustmake requests for bandwidth to the AP and wait for the allocation viapolling (e.g., in PCF mode). Consequently, both the DCF and PCF modesreduce throughput, especially in upstream traffic, due to the overheadinvolved with allocating bandwidth amongst the stations.

SUMMARY OF THE INVENTION

A system and method are disclosed for allocating bandwidth in a network.In accordance with exemplary embodiments of the present invention,according to a first aspect of the present invention, a base station forallocating bandwidth in a network includes a transceiver and a bandwidthallocation engine. During a measurement period, the bandwidth allocationengine is configured to monitor an amount of information transmitted bystations in the network to determine bandwidth required by each of thestations. After the measurement period, the transceiver is configured totransmit a bandwidth allocation message from the bandwidth allocationengine to the stations allocating bandwidth to each of the stations fortransmitting information during respective timeslots specified in thebandwidth allocation message.

According to the first aspect, the base station can comprise an accesspoint. During the measurement period, the stations can communicateinformation using a predetermined communication protocol. Thepredetermined communication protocol can comprise carrier sense multipleaccess with collision avoidance (CSMA/CA). The bandwidth allocationmessage can comprise a traffic indication map and a bandwidth assignmenttable. The bandwidth allocation message can comprise a header configuredto indicate at least a type of message. For example, the header cancomprise an I.E.E.E. 802.11 medium access control (MAC) header. Theheader can include a retry configured to indicate retransmission ofinformation. The header can include a more flag configured to indicatethat a station has additional information to transmit. The station cantransmit a null information packet to the base station with the moreflag set, when the amount of information to be communicated by thestation exceeds the timeslots allocated to the station. The bandwidthallocation message can comprise a checksum. The traffic indication mapcan be configured to identify stations allocated at least one timeslot.The bandwidth assignment table can comprise an identification portionand a timeslot allocation portion for each station allocated at leastone timeslot. The identification portion can be configured to identify astation allocated at least one timeslot. The timeslot allocation portioncan be configured to contain a number of timeslots allocated to astation.

According to the first aspect, stations allocated at least one timeslotin the bandwidth allocation message can transmit information in an orderspecified in the bandwidth assignment table. A station can enter apower-save mode for a predetermined length of time, when no timeslotsare allocated to the station in the bandwidth allocation message. Astation can transmit a null information packet to other stations toindicate an end of transmission by the station, when the amount ofinformation communicated by the station is less than the timeslotsallocated to the station. The network can comprise, for example, awireless local area network. The base station can be compatible with astandard selected from the group consisting of I.E.E.E. 802.11, 802.11a,802.11b, 802.11g, 802.11h, 802.11i, 802.11n, 802.16 and 802.20, or anysuitable wireless or wired standard. According to an exemplaryembodiment of the first aspect, a semiconductor device can comprise thebase station.

According to a second aspect of the present invention, a station forallocating bandwidth in a network includes a transceiver and aconfiguration engine. During a measurement period, the transceiver isconfigured to transmit information using a predetermined communicationprotocol. After the measurement period, the configuration engine isconfigured to receive a bandwidth allocation message allocatingbandwidth for transmitting information during respective timeslotsspecified in the bandwidth allocation message. Allocation of timeslotsin the bandwidth allocation message is based on an amount of informationtransmitted during the measurement period.

According to the second aspect, the predetermined communication protocolcan comprise CSMA/CA. The bandwidth allocation message can comprise atraffic indication map and a bandwidth assignment table. The bandwidthallocation message can comprise a header configured to indicate at leasta type of message. For example, the header can comprise an I.E.E.E.802.11 MAC header. The header can include a retry flag configured toindicate retransmission of information. The header can include a moreflag configured to indicate that the station has additional informationto transmit. The station can transmit a null information packet with themore flag set, when the amount of information to be communicated by thestation exceeds the timeslots allocated to the station. The bandwidthallocation message can comprise a checksum. The traffic indication mapcan be configured to identify stations allocated at least one timeslot.The bandwidth assignment table can comprise an identification portionand a timeslot allocation portion for each station allocated at leastone timeslot. The identification portion can be configured to identify astation allocated at least one timeslot. The timeslot allocation portioncan be configured to contain a number of timeslots allocated to astation.

According to the second aspect, stations allocated at least one timeslotin the bandwidth allocation message can transmit information in an orderspecified in the bandwidth assignment table. The station can enter apower-save mode for a predetermined length of time when no timeslots areallocated to the station in the bandwidth allocation message. Thestation can transmit a null information packet to other stations toindicate an end of transmission by the station hen the amount ofinformation communicated by the station is less than the timeslotsallocated to the station. The network can comprise, for example, awireless local area network. The station can be compatible with astandard selected from the group consisting of I.E.E.E. 802.11, 802.11a,802.11b, 802.11g, 802.11h, 802.11i, 802.11n, 802.16 and 802.20, or anysuitable wireless or wired standard. According to an exemplaryembodiment of the second aspect, a semiconductor device can comprise thestation.

According to a third aspect of the present invention, a system forallocating bandwidth in a network includes a base station and aplurality of stations in communication with the base station. During ameasurement period, the base station monitors an amount of informationcommunicated by each of the plurality of stations to determine bandwidthrequired by each of the plurality of stations. After the measurementperiod, the base station transmits a bandwidth allocation message to theplurality of stations allocating bandwidth to each of the plurality ofstations for transmitting information during respective timeslotsspecified in the bandwidth allocation message. The base station cancomprise, for example, an access point. The network can comprise awireless local area network. The system can be compatible with astandard selected from the group consisting of I.E.E.E. 802.11, 802.11a,802.11b, 802.11g, 802.11h, 802.11i, 802.11n, 802.16 and 802.20, or anysuitable wireless or wired standard.

According to a fourth aspect of the present invention, a bandwidthallocation message data structure for allocating bandwidth in a networkincludes a header data structure. The bandwidth allocation message datastructure includes a traffic indication map data structure. The trafficindication map data structure is configured to identify stations in thenetwork allocated at least one timeslot for transmitting information.The bandwidth allocation message data structure includes a bandwidthassignment table data structure. The bandwidth assignment table datastructure is configured to specie a number of timeslots allocated toeach station.

According to the fourth aspect, the header data structure can comprisean I.E.E.E. 802.11 MAC header data structure. The header data structurecan be configured to indicate at least a type of message. The headerdata structure can include a retry flag configured to indicateretransmission of information. The header data structure can include amore flag configured to indicate that a station has additionalinformation to transmit. The bandwidth allocation message data structurecan include a checksum data structure. The bandwidth assignment tabledata structure can comprise an identification data structure and atimeslot allocation data structure for each station allocated at leastone timeslot. The identification data structure of the bandwidthassignment table data structure can be configured to identify a stationallocated at least one timeslot. The timeslot allocation data structurecan be configured to contain a number of timeslots allocated to astation. According to an exemplary embodiment of the fourth aspect, thebandwidth allocation message data structure can be compatible with astandard selected from the group consisting of I.E.E.E. 802.11, 802.11a,802.11b, 802.11g, 802.11h, 802.11i, 802.11n, 802.16 and 802.20, or anysuitable wireless or wired standard.

According to a fifth aspect of the present invention, a method ofallocating bandwidth in a network includes the steps of: a.)establishing a measurement period; b.) monitoring an amount ofinformation communicated in the network during the measurement period;c.) determining bandwidth required for communicating information in thenetwork; and d.) transmitting a bandwidth allocation message, after themeasurement period, allocating bandwidth for transmitting informationduring respective timeslots specified in the bandwidth allocationmessage.

According to the fifth aspect, during the measurement period, theinformation can be communicated using a predetermined communicationprotocol. For example, the predetermined communication protocol cancomprise CSMA/CA. The bandwidth allocation message can comprise atraffic indication map and a bandwidth assignment table. The bandwidthallocation message can comprise a header configured to indicate at leasta type of message. For example, the header can comprise an I.E.E.E.802.11 MAC header. The header can include a retry flag configured toindicate retransmission of information. The header can include a moreflag configured to indicate that additional information is to betransmitted. The bandwidth allocation message can also comprise achecksum. The traffic indication map can be configured to identifystations allocated at least one timeslot. The bandwidth assignment tablecan comprise at least one timeslot allocation pair. The at least onetimeslot allocation pair can comprise an identification portion and atimeslot allocation portion. The identification portion can beconfigured to identify a station allocated at least one timeslot. Thetimeslot allocation portion can be configured to contain a number oftimeslots allocated for transmitting information. Information can becommunicated in an order specified in the bandwidth assignment table.The network can comprise a wireless local area network. The method canbe compatible with a standard selected from the group consisting ofI.E.E.E. 802.11, 802.11a, 802.11b, 802.11g, 802.11n, 802.16 and 802.20,or any suitable wireless or ed standard.

According to a sixth aspect, a method of allocating bandwidth in anetwork includes the steps of: a.) transmitting information during ameasurement period: and b.) receiving a bandwidth allocation message,after the measurement period, allocating bandwidth for transmittinginformation during respective timeslots specified in the bandwidthallocation message. Allocation of timeslots in the bandwidth allocationmessage is based on an amount of information transmitted during themeasurement period.

According to the sixth aspect, during the measurement period, theinformation can be communicated using a predetermined communicationprotocol. For example, the predetermined communication protocol cancomprise CSMA/CA. The bandwidth allocation message can comprise atraffic indication map and a bandwidth assignment table. The bandwidthallocation message can comprise a header configured to indicate at leasta type of message. For example, the header can comprise an I.E.E.E.802.11 MAC header. The header can include a retry flag configured toindicate retransmission of information. The header can include a moreflag configured to indicate that additional information is to betransmitted. The method can include the step of: c.) transmitting a nullinformation packet with the more flag set, when the amount ofinformation to be communicated exceeds allocated timeslots. Thebandwidth allocation message can comprise a checksum. The trafficindication map can be configured to identify stations allocated at leastone timeslot. The bandwidth assignment table can comprise at least onetimeslot allocation pair. The at least one timeslot allocation pair cancomprise an identification portion and a timeslot allocation portion.The identification portion can be configured to identify a stationallocated at least one timeslot. The timeslot allocation portion can beconfigured to contain a number of timeslots allocated for transmittinginformation.

According to the sixth aspect, information can be communicated in anorder specified in the bandwidth assignment table. The method caninclude the steps of: d.) entering a power-save mode for a predeterminedlength of time, when no timeslots are allocated in the bandwidthallocation message: and e.) transmitting a null information packed toindicate an end of transmission, when the amount of informationcommunicated is less than the timeslots allocated. The network cancomprise a wireless local area network. The method can be compatiblewith a standard selected from the group consisting of I.E.E.E. 802.11,802.11a, 802.11b, 802.11g, 802.11h, 802.11i, 802.11n, 802.16 and 802.20,or any suitable wireless or wired standard.

According to a seventh aspect of the present invention, a method ofallocating bandwidth in a network includes the steps of: a.)establishing a measurement period; b.) transmitting information during,the measurement period; c.) monitoring an amount of informationtransmitted in the network daring the measurement period; d.)determining bandwidth required for transmitting information in thenetwork based on an amount of information transmitted during themeasurement period; and e.) transmitting a bandwidth allocation message,after the measurement period, allocating, bandwidth for transmittinginformation during respective timeslots specified in the bandwidthallocation message. According to an exemplary embodiment of the seventhaspect, the method can be compatible with a standard selected from thegroup consisting of I.E.E.E. 802.11, 802.11a, 802.11b, 802.11g, 802.11h,802.11i, 802.11n, 802.16 and 802.20, or any suitable wireless or wiredstandard.

According to an eighth aspect of the present invention, an apparatus forallocating bandwidth in a network includes transceiver means forcommunicating, information and an allocation means for allocatingbandwidth. During a measurement period, the allocation means isconfigured to monitor an amount of information transmitted bycommunication means in the network to determine bandwidth required byeach of the communication means. After the measurement period, thetransceiver means is configured to transmit a bandwidth allocationmessage from the allocation means to the communication means allocatingbandwidth to each of the communication means for transmittinginformation during respective timeslots specified in the bandwidthallocation message.

According to the eighth aspect, the apparatus can comprise an accesspoint. During the measurement period, the communication means cancommunicate information using a predetermined communication protocol.For example, the predetermined communication protocol can compriseCSMA/CA. The bandwidth allocation message can comprise a trafficindication map and a bandwidth assignment table. The bandwidthallocation message can comprise a header configured to indicate at leasta type of message. For example, the header can comprise an I.E.E.E.802.11 MAC header. The header can include a retry flag configured toindicate retransmission of information. The header can include a moreflag configured to indicate that a communication means has additionalinformation to transmit. The communication means can transmit a nullinformation packet to the apparatus with the more flag set, when theamount of information to be communicated by the communication meansexceeds the timeslots allocated to the communication means. Thebandwidth allocation message can also comprise a checksum. The trafficindication map can be configured to identify communication meansallocated at least one timeslot. The bandwidth assignment table cancomprise an identification portion and a timeslot allocation portion foreach communication means allocated at least one timeslot. Theidentification portion can be configured to identify a communicationmeans allocated at least one timeslot. The timeslot allocation portioncan be configured to contain a number of timeslots allocated to acommunication means.

According to the eighth aspect, communication means allocated at leastone timeslot in the bandwidth allocation message can transmitinformation in an order specified in the bandwidth assignment table. Acommunication means can enter a power-save mode for a predeterminedlength of time, when no timeslots are allocated to the communicationmeans in the bandwidth allocation message. A communication means ntransmit a null information packet to other communication means toindicate an end of transmission by the communication means, when theamount of information communicated by the communication means is lessthan the timeslots allocated to the communication means. The network cancomprise a wireless local area network. The apparatus can be compatiblewith a standard selected from the group consisting of I.E.E.E. 802.11,802.11a, 802.11b, 802.11g, 802.11h, 802.11i, 802.11n, 802.16 and 802.20,or any suitable wireless or wired standard. According to an exemplaryembodiment of the eighth aspect, a semiconductor device can comprise theapparatus.

According to a ninth aspect, an apparatus for allocating bandwidth in anetwork includes transceiver means for communicating information and aconfiguration means for configuring information transmission. During ameasurement period, the transceiver means is configured to transmitinformation using a predetermined communication protocol. After themeasurement period, the configuration means is configured to receive abandwidth allocation message allocating bandwidth for transmittinginformation during respective timeslots specified in the bandwidthallocation message. Allocation of timeslots in the bandwidth allocationmessage is based on an amount of information transmitted during themeasurement period.

According to the ninth aspect, the predetermined communication protocolcan comprise CSMA/CA. The bandwidth allocation message can comprise atraffic indication map and a bandwidth assignment table. The bandwidthallocation message can comprise a header configured to indicate at leasta type of message. For example, the header can comprise an I.E.E.E.802.11 MAC header. The header can include a retry flag configured toindicate retransmission of information. The header can include a moreflag configured to indicate that the apparatus has additionalinformation to transmit. The apparatus can transmit a null informationpacket with the more flag set, when the amount of information to becommunicated by the apparatus exceeds the timeslots allocated to thestation. The bandwidth allocation message can comprise a checksum. Thetraffic indication neap can be configured to identify apparatusesallocated at least one timeslot. The bandwidth assignment table cancomprise an identification portion and a timeslot allocation portion foreach apparatus allocated at least one timeslot. The identificationportion can be configured to identify an apparatus allocated at leastone timeslot. The timeslot allocation portion can be configured tocontain a number of timeslots allocated to an apparatus.

According to the ninth aspect, apparatuses allocated at least onetimeslot in the bandwidth allocation message can transmit information inan order specified in the bandwidth assignment table. The apparatus canenter a power-save mode for a predetermined length of time, when notimeslots are allocated to the apparatus in the bandwidth allocationmessage. The apparatus can transmit a null information packet to otherapparatuses to indicate an end of transmission by the apparatus, whenthe amount of information communicated by the apparatus is less than thetimeslots allocated to the apparatus. The network can comprise awireless local area network. The apparatus can be compatible with astandard selected from the group consisting of I.E.E.E. 802.11, 802.11a,802.11b, 802.11g, 807.11h, 802.11i, 802.11n, 802.16 and 802.20.According to an exemplary embodiment of the ninth aspect, asemiconductor device can comprise the apparatus.

According to a tenth aspect of the present invention, a system forallocating bandwidth in a network includes monitoring means formonitoring the network, and a plurality of means for communicatinginformation in communication with the monitoring means. During ameasurement period, the monitoring means monitors an amount ofinformation communicated by each of the plurality of communicating meansto determine bandwidth required by each of the plurality ofcommunicating means. After the measurement period, the monitoring meanstransmits a bandwidth allocation message to the plurality ofcommunicating means allocating bandwidth to each of the plurality ofcommunicating means for transmitting information during respectivetimeslots specified in the bandwidth allocation message. The monitoringmeans can comprise an access point. The network can comprise a wirelesslocal area network. The system can be compatible with a standardselected from the group consisting of I.E.E.E. 802.11, 802.11a, 802.11b,802.11g, 802.11h, 802.11i, 802.11n, 802.16 and 802.20, or any suitablewireless or wired standard.

According to an eleventh aspect of the present invention, a system forallocating bandwidth in a wireless network, includes a base station, anda plurality of stations in communication with the base station. During ameasurement period, the base station monitors an amount of informationpackets communicated by each of the plurality of stations to determinebandwidth required by each of the plurality of stations. During themeasurement period, the plurality of stations communicate informationpackets using CSMA/CA. After the measurement period, the base stationtransmits a bandwidth allocation message to the plurality of stationsallocating bandwidth to each of the plurality of stations fortransmitting information packets during respective timeslots specifiedin the bandwidth allocation message. The bandwidth allocation messagecomprises a header, a traffic indication map, a bandwidth assignmenttable and a checksum. The traffic indication map is configured toidentify stations of the plurality of stations for which at least onetimeslot has been allocated for transmitting information packets. Thebandwidth assignment table comprises an identification portion and atimeslot allocation portion for each of the plurality of stations forwhich at least one timeslot has been allocated for transmittinginformation packets. The identification portion of the bandwidthassignment table is configured to identity a station for which the atleast one timeslot has been allocated. The timeslot allocation portionof the bandwidth assignment table is configured to contain a number oftimeslots allocated to a station for transmitting information packets.According to an exemplary embodiment of the eleventh aspect the systemcan be compatible with a standard selected from the group consisting ofI.E.E.E. 802.11, 802.11a, 802.11b, 802.11g, 802.11h, 802.11i, 802.11n,802.16 and 802.20, or any suitable wireless or wired standard.

According to a twelfth aspect of the present invention, a method ofallocating bandwidth in a wireless network includes the steps of: a.)establishing a measurement period; b.) transmitting information packetsduring the measurement period; c.) monitoring an amount of informationpackets communicated in the wireless network during the measurementperiod; d.) determining bandwidth required for communicating informationpackets in the wireless network based on an amount of informationpackets transmitted during the measurement period; e.) transmitting abandwidth allocation message, after measurement period, allocatingbandwidth for transmitting information packets during respectivetimeslots specified in the bandwidth allocation message: f.) entering apower-save mode for a predetermined length of time, when no timeslotsare allocated in the bandwidth allocation message; and g.) transmittinga null information packet to indicate an end of transmission, when theamount of information packets communicated is less than timeslotsallocated. According to an exemplary embodiment of the twelfth aspect,the method can be compatible with a standard selected from the groupconsisting of I.E.E.E. 802.11, 802.11a, 802.11b, 802.11g, 802.11n,802.16 and 802.20, or any suitable wireless or wired standard.

According to a thirteenth aspect of the present invention, a system forallocating bandwidth in a wireless network includes monitoring means formonitoring the network, and a plurality of means for communicating incommunication with the monitoring means. During a measurement period,the monitoring means monitors an amount of information packetscommunicated by each of the plurality of communicating means todetermine bandwidth required by each of the plurality of communicatingmeans. During the measurement period, the plurality of communicatingmeans communicate information packets using CSMA/CA. After themeasurement period, the monitoring means transmits a bandwidthallocation message to the plurality of communicating means allocatingbandwidth to each of the plurality of communicating means fortransmitting information packets during respective timeslots specifiedin the bandwidth allocation message. The bandwidth allocation messagecomprises a header, a traffic indication map, a bandwidth assignmentable and a checksum. The traffic indication map is configured toidentify communicating means for which at least timeslot has beenallocated for transmitting, information packets. The bandwidthassignment table comprises an identification portion and a timeslotallocation portion for each of the plurality of communicating, means forwhich at least one timeslot has been allocated for transmittinginformation packets. The identification portion of the bandwidthassignment table is configured to identify a communicating means forwhich the at least one timeslot has been allocated. The timeslotallocation portion of the bandwidth assignment table is configured tocontain a number of timeslots allocated to a communicating means fortransmitting, information packets. According to an exemplary embodimentof the thirteenth aspect, the system can be compatible with a standardselected from the group consisting of I.E.E.E. 802.11, 802.11a, 802.11b,802.11g, 802.11h, 802.11i, 802.11n, 802.16 and 802.20, or any suitablewireless or wired standard.

According to a fourteenth aspect of the present invention, a computerprogram for allocating, bandwidth in a network performs the steps of:a.) establishing a measurement period; b.) receiving an indication of anamount of information communicated in the network during the measurementperiod; c.) determining bandwidth required for communicating informationin the network; and d.) generating a bandwidth allocation message, afterthe measurement period, allocating bandwidth for transmittinginformation during respective timeslots specified in the bandwidthallocation message.

According to the fourteenth aspect, during the measurement period, theinformation can be communicated using a predetermined communicationprotocol, such as, for example, CSMA/CA or the like. The bandwidthallocation message can comprise a traffic indication map and a bandwidthassignment table. The bandwidth allocation message can comprise a headerconfigured to indicate at least a type of message. For example, theheader can comprise an I.E.E.E. 802.11 MAC header or the like. Theheader can include a retry flag configured to indicate retransmission ofinformation. The header can include a more flag configured to indicatethat additional information is to be transmitted. The bandwidthallocation message can comprise a checksum. The traffic indication mapcan be configured to identify stations allocated at least one timeslot.

According to the fourteenth aspect, the bandwidth assignment table cancomprise at least one timeslot allocation pair. The at least onetimeslot allocation pair can comprise an identification portion and atimeslot allocation portion. The identification portion can beconfigured to identify a station allocated at least one timeslot. Thetimeslot allocation portion can be configured to contain a numbertimeslots allocated for transmitting information. Information can becommunicated in an order specified in the bandwidth assignment table.The network can comprise, for example, a wireless local area network.The steps performed by the computer program can be compatible with astandard selected from the group consisting of I.E.E.E. 802.11, 802.11a,802.11b, 802.11g, 802.11n, 802.16 and 802.20, or any suitable wirelessor wired standard.

According to a fifteenth aspect of the present invention, a computerprogram for allocating bandwidth in a network performs the steps of: a.)providing information for transmission during a measurement period; andb.) receiving a bandwidth allocation message, after the measurementperiod, allocating bandwidth for transmitting information duringrespective timeslots specified in the bandwidth allocation message,wherein allocation of timeslots in the bandwidth allocation message isbased on an amount of information transmitted during the measurementperiod.

According to the fifteenth aspect, during the measurement period, theinformation can be transmitted using a predetermined communicationprotocol, such as, for example, CSMA/CA or the like. The bandwidthallocation message can comprise a traffic indication map and a bandwidthassignment table. The bandwidth allocation message can comprise a headerconfigured to indicate at least a type of message. For example, theheader can comprise an I.E.E.E. 802.11 MAC header or the like. Theheader can include a retry flag configured to indicate retransmission ofinformation. The header can include a more flag configured to indicatethat additional information is to be transmitted. The computer programcan perform the step of: c.) generating a null information packet withthe more flag set, when the amount of information to be communicatedexceeds allocated timeslots. The bandwidth allocation message cancomprise a checksum. The traffic indication map can be configured toidentify stations allocated at least one timeslot.

According to the fifteenth aspect, the bandwidth assignment table cancomprise at least one timeslot allocation pair. The at least onetimeslot allocation pair can comprise an identification portion and atimeslot allocation portion. The identification portion can beconfigured to identify a station allocated at least one timeslot. Thetimeslot allocation portion can be configured to contain a number oftimeslots allocated for transmitting information. Information can betransmitted in an order specified in the bandwidth assignment table. Thecomputer program can perform the step of: d.) generating a signal toenter a power-save mode for a predetermined length of time, when notimeslots are allocated in the bandwidth allocation message; and e.)generating a null information packet to indicate an end of transmission,when the amount of information communicated is less than the timeslotsallocated. The network can comprise, for example, a wireless local areanetwork. The steps performed by the computer program can be compatiblewith a standard selected from the group consisting of I.E.E.E. 802.11,802.111a, 802.11b, 802.11g, 902.11n, 802.16 and 802.20, or any suitablewireless or wired standard.

According to a sixteenth aspect of the present invention a computerprogram for allocating bandwidth in a network performs steps of: a.)establishing a measurement period; b.) providing information fortransmission during the measurement period; c.) receiving an indicationof an amount of information transmitted in the network during themeasurement period; d.) determining bandwidth required for transmittinginformation in the network based on an amount of information transmittedduring the measurement period; and e.) generating a bandwidth allocationmessage, after the measurement period, allocating bandwidth fortransmitting information during respective timeslots specified in thebandwidth allocation message. The steps performed by the computerprogram can be compatible with a standard selected from the groupconsisting of I.E.E.E. 802.11, 802.11a, 802.11b, 802.11g, 802.11n,802.16 and 802.20 or any suitable wireless or wired standard.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects and advantages of the present invention will becomeapparent to those skilled in the art upon reading the following detaileddescription of preferred embodiments, in conjunction with theaccompanying drawings, wherein like reference numerals have been used todesignate like elements, and wherein:

FIGS. 1A, 1B and 1C are diagrams illustrating a system, base station,and station, respectively, for estimating bandwidth requirements of andallocating bandwidth to communication devices operating in a network, inaccordance with an exemplary embodiment of the present invention.

FIGS. 2A and 2B are diagrams illustrating a bandwidth allocationmessage, in accordance with an exemplary embodiment of the presentinvention.

FIG. 3 illustrates a header of a bandwidth allocation message comprisingat I.E.E.E. 802.11 medium access control (MAC) management frame, inaccordance with an exemplary embodiment of the present invention.

FIG. 4 is a flowchart illustrating steps for allocating bandwidth in anetwork, in accordance with an exemplary embodiment of the presentinvention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Exemplary embodiments of the present invention are directed to a systemand method for estimating bandwidth requirements of and allocatingbandwidth to communication devices operating in a network, referred toherein as “predictive medium access control (MAC).” According toexemplary embodiments, bandwidth demand is calculated for all activestations in a wireless local area network (WLAN) by a base station, suchas, for example, an Access Point (AP), and a bandwidth allocation schemeis used to allow stations to transmit data in an orderly fashion.Stations working in the same WLAN do not need to make requests forbandwidth. Instead, the AP establishes measurement periods in which tomonitor the bandwidth utilized by each transmitting station. During thismeasurement period, the stations employ a conventional carrier sensemultiple access with collision avoidance (CSMA/CA) scheme fortransmitting data. From the data collected during the measurementperiods, the AP estimates the bandwidth to be required by eachtransmitting station. The AP then transmits a traffic allocation frameto all stations at regular intervals. The duration of such intervalssatisfies the bandwidth requirements of all stations detected during themeasurement period. The traffic allocation frame contains: a bit map toindicate the identification of the stations for which one or moretimeslots have been allocated by the AP for transmission: and abandwidth assignment table indicating the number of timeslots allocatedto each station specified in the bit map. Upon receiving the trafficallocation frame, the stations to which timeslots have been allocateduse the information contained in the hit map and the bandwidthassignment table to determine their order of transmission.

The number of timeslots assigned by the AP to each station can beadjusted in accordance with the level of traffic from the stations, asdetermined by the AP during the measurement periods. If a station doesnot need all of the timeslots allocated to it, the AP can reduce thenumber of timeslots allocated to the station by, for example, one ormore. If a station needs more timeslots than allocated to it, the AP canincrease the number of timeslots allocated to the station by, forexample, one or more. In addition if a station has no timeslotsallocated to it in a traffic allocation frame, then the station canchoose to enter into a sleep or low-power mode for a period equal to thesum of all allocated timeslots. Upon waking up, if the station hasinformation to transmit, the station will wait until after the nexttraffic allocation frame has arrived and all stations with allocatedtimeslots complete their transmission, before the station beginstransmitting its information during the subsequent measurement period.

These and other aspects of the present invention will now be describedin greater detail. FIG. 1A is a diagram illustrating a system 100 forestimating bandwidth requirements of and allocating bandwidth tocommunication devices operating in a network, in accordance with anexemplary embodiment of the present invention. FIG. 1A can represent,for example, cells of a WLAN or the like, although FIG. 1A can representany suitable network. The system 100 includes a base station 105. Thebase station 105 can comprise a network monitor element such as, forexample, an AP or other suitable network monitoring device. The system100 also includes a plurality of clients or stations 110 incommunication with the base station 105 over, for example, wirelesscommunication channels 115 or other suitable communication medium. Thenetwork 100 can include any number of stations 110 (i.e., Station 0,Station 1, Station 2, . . . , Station (N-1)).

According to exemplary embodiments, during a measurement period, thebase station 105 monitors an amount of information communicated by eachof the plurality of stations 110 to determine bandwidth required by eachof the plurality of stations 110. More particularly, the base station105 establishes one or more measurement periods, each of which being anysuitable length of time for monitoring the bandwidth utilized by each ofthe stations 110. The length of a measurement period can depend on, forexample, the amount of information transmitted by the stations 110, andthe like. During the measurement period, the plurality of stations 110communicate information packets using a predetermined communicationprotocol. For example, the stations 110 can communicate using a CSMA/CAscheme or other suitable communication protocol. From the data collectedduring the measurement periods, the base station 105 can estimate orotherwise project the bandwidth to be required by each of the stations110.

Consequently, after each measurement period, the base station 105transmits a bandwidth allocation message to the plurality of stations110 allocating bandwidth to each of the plurality of stations 110 fortransmitting information during respective timeslots specified in thebandwidth allocation message. The bandwidth allocation messages aretransmitted at regular intervals by the base station 105. According toexemplary embodiments, the duration of the intervals and the frequencywith which the bandwidth allocation messages are transmitted is designedto satisfy the bandwidth requirements of the plurality of stations 110.For example, the length of time between transmission of bandwidthallocation messages can allow for the stations 110 to transmit using, aDistributed Coordinated Function (DCF) mode or the like. Upon receivingthe bandwidth allocation message, the stations 110 for which one or moreslots have been allocated use the information contained in the bandwidthallocation message to determine their respective order of transmission.Thus, according to exemplary embodiments, stations 110 make implicit,rather than explicit, requests for bandwidth, and do not wait for a pollmessage from the base station 105 to determine how much and in whatorder the stations 110 are to transmit.

According to exemplary embodiments, the base station 105 can estimate orotherwise project the bandwidth to be required by each of the stations110 using any suitable method. For purposes of illustration and notlimitation, assume that the system 100 includes three stations: Station0, Station 1 and Station 2. During a measurement period established bythe base station 105. Station 0 accesses the Internet intermittently.Station 1 performs numerous file uploads, and Station 2 performsnumerous file downloads. From the amount of information transmitted byeach station the base station 105 calculates that Station 0 transmitsdata at a rate of for example, 56 KB/sec, while Station 1 transmits dataat a rate of, for example, 2 MB/sec. Although Station 2 is receivinglarge amounts of data, it is only sending TCP ACKs response to receivingthe data). Consequently the base station 105 can determine that Station2 has an effective throughput of 256 KB/sec. Based on this information,the base station 105 can allocate the appropriate number of timeslots toeach station for transmitting data during their respective timeallocations.

FIGS. 1B and 1C are diagrams illustrating the base station 105 andstation 110 for estimating bandwidth requirements of and allocatingbandwidth to communication devices operating in a network, in accordancewith an exemplary embodiment of the present invention. As illustrated inFIG. 1B, the base station 105 includes a transceiver 143 forcommunicating information. The base station 105 can include any suitableadditional components necessary for transmitting and receivinginformation, such as, for example, a baseband processor 145 and thelike. The base station 105 also includes a medium access control (MAC)layer 147, including a bandwidth allocation engine 149. The bandwidthallocation engine 149 is configured to, for example, monitor the amountof information transmitted by stations 110 in the network during eachmeasurement period to determine the bandwidth required by each of thestations 110. The transceiver 143 is configured to transmit, after themeasurement period, the bandwidth allocation message from the bandwidthallocation engine 149 to the stations 110 allocating bandwidth to eachof the stations 110 for transmitting information during respectivetimeslots specified in the bandwidth allocation message. The MAC layer147 can also include any suitable additional engines for managing orotherwise directing information communication in the network, such as,for example, SSID generator engines, power selector engines, detectorengines, verification/authorization engines, and the like. The basestation 105 can also include an antenna 141.

As illustrated in FIG. 1C, a station 110 includes a transceiver 153 forcommunicating information. The station 110 can include any suitableadditional components necessary for transmitting and receivinginformation, such as, for example, a baseband processor 155 and thelike. The transceiver 153 is configured to transmit information using apredetermined communication protocol, such as, for example, CSMA/CA orthe like, during the measurement period. The station 110 also includes aMAC layer 157, including a configuration engine 159. The configurationengine 159 is configured to receive, after the measurement period, thebandwidth allocation message allocating bandwidth for transmittinginformation during respective timeslots specified in the bandwidthallocation message. The MAC layer 157 can also include an suitableadditional engines for communicating information in the network, suchas, for example, SSID generator engines, power selector engines,detector engines, verification/authorization engines, and the like. Thestation 110 can also include an antenna 151.

FIGS. 2A and 2B are diagrams illustrating a bandwidth allocation message200, in accordance exemplary embodiment of the present invention. Asillustrated in FIG. 2A, the bandwidth allocation message 200 comprises atraffic indication snap 205 and a bandwidth assignment table 210.According to exemplary embodiments, the traffic indication map 205 isconfigured to identify stations 110 of the plurality of stations 110 forwhich at least one timeslot has been allocated for transmittinginformation. For example, the traffic indication map 205 can becomprised of a bit map, of any suitable length, in which each bit of thebit map corresponds to one of the plurality of stations 110. Forexample, bit position zero can correspond to Station 0, bit position onecan correspond to Station 1, bit position two can correspond to Station2, and the like. For each bit position a zero value represents that thecorresponding station 110 has not been allocated any timeslots by thebase station 105, while a one value represents that the correspondingstation 110 has been allocated one or more timeslots. In one exemplaryembodiment, the traffic indication map 205 can be comprised of 256 bitsto support up to 256 stations. However, the traffic indication map 205can be comprised of an suitable number of bits to support up to anyappropriate number of stations 110.

Upon receipt of the bandwidth allocation message 200, each station 110can check its corresponding bit position in the traffic indication map205 to determine whether one or more timeslots have been allocated tothe respective station 110. If the corresponding bit position is set toa one value, the station 110 can then check the bandwidth assignmenttable 210 to determine how many timeslots have been allocated to thestation 110 for transmitting information.

As illustrated in FIG. 2B, according to exemplary embodiments, thebandwidth assignment table 210 comprises a plurality of timeslotallocation pairs 230, one pair for each of the plurality of stations 110for which at least one timeslot has been allocated for transmittinginformation. In other words, each station 110 allocated one or moretimeslots by the base station 105 (as indicated by a one value in thecorresponding bit position of the traffic indication map 205) will havea corresponding timeslot allocation pair 230 in the bandwidth assignmenttable 210. Each timeslot allocation pair 230 is comprised of anidentification portion 233 and a timeslot allocation portion 237. Theidentification portion 233 is configured to identify a station 110 forwhich the at least one timeslot has been allocated. The correspondingtimeslot allocation portion 237 is configured to contain the number oftimeslots allocated to the station 110, identified in the correspondingidentification portion 233, for transmitting information.

According to an exemplary embodiment each timeslot allocation pair 230can be comprised of for example, two bytes, where the first byte is usedfor the identification portion 233 and the second byte is used for thetimeslot allocation portion 237. However each timeslot allocation pair230 can be of any suitable size.

For purposes of illustration and not limitation, assume that the system100 includes three stations: Station 0, Station 1 and Station 2. Duringa measurement period. Stations 0, 1 and 2 are determined to betransmitting information at the respective rates discussed in theprevious illustration. In the present illustration, assume that based onthe information collected during the measurement period, the basestation 105 estimates that Station 0 requires no timeslots. Station 1requires fifteen timeslots for transmitting data, and Station 2 requiressix timeslots. In such a situation, in the traffic indication map 205base station 105 sets each of hit position 1 (corresponding to Station1) and bit position 2 (corresponding to Station 2) to a one value,indication that one or more timeslots have been allocated to each ofthese stations (bit position 0, corresponding to Station 0, is a zerovalue, because no timeslots are allocated to Station 0).

Consequently, the first timeslot allocation pair 230 of bandwidthassignment table 210 corresponds to Station 1, with the identificationportion 233 of that pair set to one (corresponding to Station 1) and thetimeslot allocation portion 237 of that pair set to fifteen(representing the number of timeslots allocated to Station 1). Thesecond timeslot allocation pair 230 corresponds to Station 2, with theidentification portion 233 of that pair set to two (corresponding toStation 2) and the timeslot allocation portion 237 of that pair set tosix (representing the number of timeslots allocated to Station 2). Notethat Station 0 does not have a corresponding timeslot allocation pair230 in bandwidth assignment table 210, as no timeslots are allocated toStation 0. According to an alternative exemplary embodiment, however,each station 110 can have a corresponding timeslot allocation pair 230in the bandwidth assignment table 210. In such an alternative exemplaryembodiment, if no timeslots are allocated to a particular station 110,then the timeslot allocation portion 237 of the timeslot allocation pair230 corresponding to that station 110 can be set to zero.

The stations 110 allocated at least one timeslot in the bandwidthallocation message 210 transmit information in the order specified inthe bandwidth assignment table 210. Thus, according to exemplaryembodiments, the order of transmission of the stations 110 can beprioritized. For example, if a particular station 110 is transmittinghigh priority traffic, base station 105 can move the timeslot allocationpair 230 corresponding to that station 110 to the beginning of thebandwidth assignment table 210. Consequently, the order of transmissionof the stations 110 can be changed or otherwise altered by the basestation 105 by rearranging or otherwise reordering the timeslotallocation pairs 230 in the bandwidth assignment table 210 to supportthe desired transmission order. Thus exemplary embodiments of thepresent invention can support quality of service (QoS).

According to exemplary embodiments, the station 110 listed first in thebandwidth assignment table 210 begins transmission a predeterminedlength of time after it receives the bandwidth allocation message 200.The predetermined length of time can be any suitable length of time toallow the (first) station 110 to switch from a receiving mode to atransmitting mode, and can be on the order of, for example, microseconds(e.g., 10 μsecs) or appropriate length of time. The station 110 listedsecond in the bandwidth assignment table 210 can then begin transmittingafter the predetermined length of time plus the number of timeslotsallocated to the station 110 listed first. The station 110 listed thirdin the bandwidth assignment table 210 can then begin transmitting afterthe predetermined length of time plus the number of timeslots allocatedto the stations 110 listed first and second, and the like. After thepredetermined length of time plus the total number of timeslotsallocated to the stations 110 (plus any additional overhead time), thebase station 105 can enter another measurement period and determinesubsequent bandwidth requirements of each of the stations 110.

The length of a timeslot can be any suitable length of time, forexample, on the order of microseconds (e.g., 32 μsecs) or anyappropriate length of time. However, the length of the timeslot can beconfigurable, with the timeslot length depending on, for example, thenumber of stations 110 in the network, the amount of informationtransmitted by each of the stations 110, the type of network, and thelike.

According to exemplary embodiments, a station 110 of the plurality ofstations 110 can enter a power-save or low-power mode for apredetermined length of time, when the station 110 is not allocated atleast one timeslot in the bandwidth allocation message 200. Thus, bychecking the traffic indication map 205, the station 110 can determinewhether or not it has been allocated timeslots. The predetermined lengthof time can be computed such that the station 110 “wakes up” beforetransmission from the other stations 110 with allocated timeslots iscomplete. For example, the station 110 can safely enter such apower-save or low-power mode for a period of time equal to the number ofall timeslots allocated to other stations 110 multiplied by the lengthof a timeslot, minus, for example, an adjustment time (e.g., an earlywake-up time so that the station 110 “wakes up” just prior to the end ofthe last transmission). Alternatively, the predetermined length of timecan be calculated by using at most one timeslot for each station 110that has been allocated timeslots. Other like methods for computing thepredetermined length of time can be used. As discussed below, therecould be an early termination of all allocated timeslots. In such asituation, the “sleeping” station 110 may wake up late and may miss themeasurement period in which its bandwidth requirement is would bedetermined by the base station 105. However, according to exemplaryembodiments, the late-waking station 110 can simply wait for the nextmeasurement period to compete for allocated timeslots.

The bandwidth allocation message 200 includes a header 215. The header215 is configured to indicate at least a type of message (e.g., amanagement message). Additionally, the header 215 can include a moreflag configured to indicate that a station 110 has additionalinformation to transmit, and can include a retry flag configured toindicate retransmission of information by a station 110.

According to exemplary embodiments, the station 110 transmits a nullinformation packet to the base station 105 with the more flag set, whenthe amount of information to be communicated by the station 110 exceedsthe timeslots allocated to the station 110. A “null information packet”is a bandwidth allocation message 200 with a header and no body (i.e., atraffic indication map 205 and bandwidth assignment table 210 of zerolength). For purposes of illustration and not limitation, if the station110 has been allocated five timeslots, but has seven timeslots worth ofinformation to transmit, the station 110 can request additionaltimeslots using the more flag. The null information packet with the moreflag set can be sent by the station 110 before the end of the timeslotsallocated to it, such as, for example, after the fourth timeslot in thepresent illustration. The base station 105 receives the null informationpacket from the particular station 110 and examines the more flag todetermine whether the number of timeslots currently allocated to thestation 110 should be increased. If the base station 105 determines thatthe number of timeslots allocated to the given station 110 should beincreased, then the base station 105 will increase the number oftimeslots for the given station 110 in the next bandwidth allocationmessage 200 sent after the next measurement period by, for example, oneor more timeslots. According to an alternative exemplary embodiment, thestation 110 can set the more flag in the last packet it transmits thebase station 105 to request additional timeslots, rather than in a nullinformation packet.

In addition, if a given station 110 needs to continue transmission untilit receives, for example, an acknowledgment, the station 110 can requestadditional timeslots using the retry flag. The null information packetwith the retry flag set can be sent by the given station 110 before theend of the timeslots allocated to it. The base station 105 receives thenull information packet from the given station 110 and examines theretry flag to determine whether the number of timeslots currentlyallocated to the station 110 should he increased. If the base station105 allocates additional timeslots to the station 110, then, after thenext measurement period, the base station 105 can transmit a bandwidthallocation message 200 with the retry flag set (to indicate thatadditional transmission time has been granted) and the number ofallocated timeslots in timeslot allocation portion 233 corresponding tothe given station 110 increased to accommodate the additionaltransmission, such as, for example, by one or more timeslots. In thealternative, if the base station 105 does not allocate additionaltimeslots to the given station 110, the base station 105 transmits abandwidth allocation message 200 with the retry flag unset, therebyindicating to the given station 110 that its request for additionaltimeslots has been denied.

According to exemplary embodiments, a station 110 transmits a formationpacket to the plurality to stations 110 to indicate an end oftransmission by the station 110, when the amount of informationcommunicated by the station 110 is less than the timeslots allocated tothe station 110. Thus, for purposes of illustration and not limitation,if a given station 110 has been allocated five timeslots, but has enoughinformation to fill two timeslots, then the given station 110 can send anull information packet after its second timeslot to the other stations110 in the network to indicate an end of transmission. Upon receipt ofsuch a null information packet, the other stations 110 can adjust thestart of their respective transmission times to begin transmissionearlier. In addition, the base station 110 can decrease the number oftimeslots allocated to the given station 110 in the next bandwidthallocation message 110 by, for example, one or more timeslots.

The bandwidth allocation message 200 can also include a checksum 225.The checksum 225 can be, for example, a 32-bit cyclic redundancy code(CRC), as specified for I.E.E.E. 802.11 (hereinafter “802.11”) frames,or any suitable checksum. The checksum 225 can be calculated over allfields of the header 215, traffic indication map 205, and bandwidthassignment table 210.

According to exemplary embodiments, the system 100 can be compatiblewith a standard selected from the group consisting I.E.E.E. 802.11,802.11a, 802.11b, 802.11g, 802.11h, 802.11i, 802.11n, 802.16 and 802.20,or any other suitable wireless or wired standard. For example, accordingto one exemplary embodiment of the present invention, for a 802.11 WLAN,the bandwidth allocation message 200 can comprise a 802.11 MACmanagement frame, with the header 215 comprising a 802.11 MAC header andthe traffic indication map 205 and bandwidth assignment table 210forming the frame body of the 802.11 MAC management frame.

FIG. 3 illustrates the header 215 of the bandwidth allocation message200 comprising a 802.11 MAC management frame, in accordance with anexemplary embodiment of the present invention. In FIG. 1 the first twobytes of header 215 comprise Frame Control 305. Frame control 305 iscomprised of eleven subfields. The first subfield is Protocol Version306 (two bits), that allows two versions of the protocol to operate atthe same time in the same cell. The next subfield is Type 307 (twobits), that specifies whether the frame is either a data, control ormanagement frame. For a management frame, bits B2 and B3 would be 0 and0. The next subfield is Subtype 308 (four bits), that further definesthe data, control or management frame specified in Type 307, as eachframe type has several different subtypes. The To DS 309 and From DS 310(each one bit) indicate that the frame is either going to or coming fromthe intercell Distribution System (DS). The next subfield is MoreFragments 311 (one bit), that indicates that more frame fragments of thecurrent frame, are to follow. The next subfield is Retry 312 (one bit),that marks a retransmission of a frame previously sent. According toexemplary embodiments, Retry 312 can be used as the retry flag discussedpreviously. Power Management 313 (one bit) is used by the AP to put thereceiving station into a sleep state or take the station out of sleepstate. The next subfield is More Data 314 (one bit), that indicates thatthe sender has additional frames for the receiver. According toexemplary embodiments, More Data 314 can be used as the more flag by astation 110 to request additional timeslots. The WEP 315 hit specifiesthat the frame body has been encrypted using the Wired EquivalentPrivacy (WEP) algorithm. The final subfield is Order 316 (one bit), thattells the receiver that a sequence of frames with this bit on must beprocessed strictly in order.

The next two bytes of header 215 can comprise Duration 320, thatspecifies how long the frame and its acknowledgment will occupy thechannel. The next six bytes of header 215 can comprise DestinationAddress 325, that indicates the address of the destination of the frame.The Source Address 330 (six bytes) indicates the address of the devicetransmitting the frame. The BSSID 335 (six bytes) uniquely identifiesthe cell or Basic Service Set (BSS) in which the station or AP islocated. Sequence 340 (two bytes) allows frame fragments to be numbered.However, other frame formats for header 215 and bandwidth allocationmessage 200 are possible, depending on, for example, the type of network(e.g., wireless or wired) in which the bandwidth allocation message 200is to be used, the type of protocol used for communicating informationin that network, and the like.

Additionally, according to exemplary embodiments, the base station 105and stations 110 can each be compatible with a standard selected fromthe group consisting of I.E.E.E. 802.11, 802.11a, 802.11b, 802.11g,802.11h, 802.11i, 802.11n, 802.16 and 802.20, or any suitable wirelessor wired standard. Base station 105 and each of the plurality ofstations 110 can be comprised of any suitable type of electrical orelectronic components or devices that are capable of performing thefunctions associated with the respective element. According to analternative exemplary embodiment, the base station 105 and stations 110can each be comprised of any suitable semiconductor device. In addition,base station 105 can be in communication with other systems 130 (e.g.,other cells or other networks) through the intercell DS via a wirelesscommunications channel 120 to a router 125. The router 125 can be incommunication with other systems 130 using any suitable form ofcommunications medium for communicating electrical signals throughoutthe intercell DS.

FIG. 4 is a flowchart illustrating steps for allocating bandwidth in anetwork, in accordance with an exemplary embodiment of the presentinvention. In step 405, a measurement period is established by the basestation 105. During the measurement period, in step 410, information istransmitted by the stations 110. The information can be transmittedusing a predetermined communication protocol, such as for example,CSMA/CA, or any suitable communication protocol. Also during themeasurement period, in step 415, the base station 105 monitors an amountof information communicated in the network by the stations 110. In step420, the base station 105 determines the bandwidth required by eachstation 110 for communicating information in the network. After themeasurement period, in step 425, a bandwidth allocation message istransmitted allocating, bandwidth for transmitting information duringrespective timeslots specified in the bandwidth allocation message. Instep 430 a bandwidth allocation message is received by the stations 110,after the measurement period, allocating bandwidth for transmittinginformation packets during respective timeslots specified in thebandwidth allocation message. Allocation of timeslots in the bandwidthallocation message is based on an amount of information packetstransmitted during the measurement period.

Optionally, in step 435, a null information packet with the more flagset can be transmitted by a station 110 to the base station 105, whenthe amount of information to be communicated by the station 110 exceedsthe number of timeslots allocated to the station 110. Optionally, instep 440, the base station 105 can increase the number of timeslotsallocated to the station 110 in the next bandwidth allocation messageby, for example, one or more timeslots. Optionally, in step 445, astation 110 can enter a power-save mode for a predetermined length oftime when timeslots are allocated in the bandwidth allocation message tothe given station 110. Optionally, in step 450, a null informationpacket can be transmitted by a station 110 to indicate an end oftransmission by the station 110, when the amount of information packetscommunicated is less than the timeslots allocated to the station 110.Optionally, in step 455, the base station 105 can decrease the number oftimeslots allocated to the station 110 in the next bandwidth allocationby, for example, one or more timeslots.

According to exemplary embodiments, the method illustrated in FIG. 4 canbe compatible with a standard selected from the group consisting ofI.E.E.E. 802.11, 802.11a, 802.11b, 802.11g, 802.11h, 802.11i, 802.11n,802.16 and 802.20, or any suitable wireless or wired standard.

Additionally, the steps of a computer program as illustrated in FIG. 4for allocating bandwidth in a network and the data structure forbandwidth allocation message 200 disclosed herein can be embodied in anycomputer-readable medium for use by or in connection with an instructionexecution system apparatus, or device, such as a computer-based system,processor-containing system, or other system that can fetch theinstructions from the instruction execution system, apparatus, or deviceand execute the instructions. As used herein, a “computer-readablemedium” can be any means that can contain, store, communicate,propagate, or transport the program for use by or in connection with theinstruction execution system, apparatus, or device. The computerreadable medium can be, for example but not limited to, an electronic,magnetic, optical, electromagnetic, infrared, or semiconductor system,apparatus, device, or propagation medium. More specific examples (anon-exhaustive list) of the computer-readable medium can include thefollowing: an electrical connection having one or more wires, a portablecomputer diskette, a random access memory (RAM), a read-only memory(ROM), an erasable programmable read-only memory (EPROM or Flashmemory), an optical fiber, and a portable compact disc read-only memory(CDROM).

It will be appreciated by those of ordinary skill in the art that thepresent invention can be embodied in various specific forms withoutdeparting from the spirit or essential characteristics thereof. Thepresently disclosed embodiments are considered in all respects to beillustrative and not restrictive. The scope of the invention isindicated by the appended claims, rather than the foregoing description,and all changes that come within the meaning and range of equivalencethereof are intended to be embraced.

All United States patents and applications, foreign patents, andpublications discussed above are hereby incorporated herein by referencein their entireties.

1. (canceled)
 2. A system comprising: a plurality of stations configuredto transmit packets; and a base station configured to estimatebandwidths used by the plurality of stations based on packetstransmitted by the plurality of stations during a first period, andselectively allocate timeslots to the plurality of stations fortransmission of packets to the base station during a second period,wherein the second period follows the first period, wherein durations ofthe timeslots are based on the estimated bandwidths, and wherein theplurality of stations are further configured to transmit packets to thebase station in the timeslots during the second period.
 3. The system ofclaim 2, wherein the base station is further configured to transmit amessage comprising (i) identification of the plurality of stations towhich one or more of the timeslots are allocated, and (ii) a number ofthe timeslots allocated to each of the identified stations.
 4. Thesystem of claim 2, wherein each of the plurality of stations isconfigured to transmit packets to the base station during the secondperiod in an order determined by a number of the timeslots allocated toeach of the plurality of stations.
 5. The system of claim 2, wherein thebase station is further configured to adjust a number of the timeslotsallocated to each of the plurality of stations based on needs of theplurality of stations.
 6. The system of claim 3, wherein, in response tothe base station not allocating any of the timeslots to the one of theplurality of stations, one of the plurality of stations is configured toenter a sleep mode or a low-power mode for a period equal to a sum ofthe timeslots.
 7. The system of claim 6, wherein when the one of theplurality of stations exits the sleep mode or the low-power mode, theone of the plurality of stations is configured to transmit packets after(i) a next one of the message is received, and (ii) all of the pluralityof stations to which the timeslots are allocated complete transmission.8. A base station comprising: a control module configured to estimatebandwidths used by a plurality of stations based on packets transmittedby the plurality of stations during a first period, and selectivelyallocate timeslots to the plurality of stations to transmit packets tothe base station during a second period, wherein the second periodfollows the first period, wherein durations of the timeslots are basedon the estimated bandwidths; and a transceiver configured to receivepackets transmitted by the plurality of stations in the timeslots duringthe second period.
 9. The base station of claim 8, wherein: the controlmodule is further configured to generate a message comprising (i)identification of the plurality of stations to which one or more of thetimeslots are allocated, and (ii) a number of the timeslots allocated toeach of the identified stations; and the transceiver is furtherconfigured to transmit the message to the plurality of stations.
 10. Thebase station of claim 8, wherein the timeslots allocated to each of theplurality of stations determines an order in which each of the pluralityof stations transmits packets to the base station during the secondperiod.
 11. The base station of claim 8, wherein the control module isfurther configured to adjust a number of the timeslots allocated to eachof the plurality of stations based on needs of the plurality ofstations.
 12. A system comprising: the base station of claim 9; and theplurality of stations, wherein, in response to the base station notallocating any of the timeslots to the one of the plurality of stations,one of the plurality of stations is configured to enter a sleep mode ora low-power mode for a period equal to a sum of the timeslots.
 13. Thesystem of claim 12, wherein when the one of the plurality of stationsexits the sleep mode or the low-power mode, the one of the plurality ofstations is configured to transmit packets after (i) a next one of themessage is received, and (ii) all of the plurality of stations to whichthe timeslots are allocated complete transmission.
 14. A stationcomprising: a transceiver configured to transmit packets to a basestation during a first period, and receive a timeslot allocated by thebase station to the station to transmit packets to the base stationduring a second period, wherein the second period follows the firstperiod, wherein a duration of the timeslot is based on a bandwidth usedby the station to transmit packets to the base station during the firstperiod; and a control module configured to cause the transceiver totransmit packets to the base station in the timeslot during the secondperiod.
 15. A system comprising: a plurality of stations including thestation of claim 14; and the base station, wherein the base station isconfigured to receive packets from the plurality of stations during thefirst period, estimate bandwidths used by the plurality of stations totransmit packets during the first period, wherein the bandwidths includethe bandwidth used by the station to transmit packets during the firstperiod, and selectively allocate timeslots to the plurality of stationsto transmit packets to the base station during the second period,wherein the timeslots include the timeslot.
 16. The system of claim 15,wherein the base station is further configured to transmit a messagecomprising (i) identification of the plurality of stations to which oneor more of the timeslots are allocated, and (ii) a number of thetimeslots allocated to each of the identified stations.
 17. The systemof claim 15, wherein each of the plurality of stations is configured totransmit packets to the base station during the second period in anorder determined by a number of the timeslots allocated to each of theplurality of stations.
 18. The system of claim 15, wherein the basestation is further configured to adjust a number of the timeslotsallocated to each of the plurality of stations based on needs of theplurality of stations.
 19. The system of claim 16, wherein, in responseto the base station not allocating any of the timeslots to the one ofthe plurality of stations, one of the plurality of stations isconfigured to enter a sleep mode or a low-power mode for a period equalto a sum of the timeslots.
 20. The system of claim 19, wherein when theone of the plurality of stations exits the sleep mode or the low-powermode, the one of the plurality of stations is configured to transmitpackets after (i) a next one of the message is received, and (ii) all ofthe plurality of stations to which the timeslots are allocated completetransmission.